A method of estimating the amount of calcium bound to the metallochromic indicator arsenazo III

As a metallochromic indicator for ionized calcium, arsenazo III is approximately 50 times more sensitive than murexide. However, because of the high binding constant for calcium, the following problems may occur: (a) a considerable amount of calcium is bound to arsenazo III, thereby causing an error in estimating the concentration of ionized calcium; (b) the amount of bound calcium varies with the concentrations of calcium, arsenazo III, magnesium ion and monovalent cations; (c) the amount also varies with pH, (d) the relationship between the absorbance change and the concentration of ionized calcium is nonlinear; and (e) the binding constant of arsenazo III for calcium cannot be determined by the conventional double reciprocal plot. A new experimental and theoretical method is presented which copes with these problems.     

Interaction of metallochromic indicators with calcium sequestering organelles.

Examples are presented of the interaction between cell organelles and metallochromic indicators used in the measurement of ionized Ca2+. Sarcoplasmic reticulum was found to sequester murexide type indicators along with Ca2+ in the presence of ATP, but not to sequester arsenazo III and antipyrylazo III. The presence of a permeable anion suppresses the sequestration of murexide type indicators by the sarcoplasmic reticulum. In the presence of ruthenium red, both rat liver and beef heart mitochondria release sequestered Ca2+ with arsenazo III, but not with murexide.     

Reduction of the metallochromic indicators arsenazo III and antipyrylazo III to their free radical metabolites by cytoplasmic enzymes

At a concentration much lower than that usually employed for measuring cytosolic ionized Ca²⁺ concentrations, arsenazo III underwent a one-electron reduction by rat liver cytosolic fraction or a hypoxanthinexanthine oxidase system to produce an azo anion radical metabolite. NADH, NADPH, N¹-methylnicotinamide, hypoxanthine, and xanthine, in that order, could serve as a source of reducing equivalents for the production of this free radical by the cytosolic fraction. The steady-state concentration of the azo anion radical and the arsenazo III-stimulated O₂ consumption were enhanced by calcium and magnesium. Antipyrylazo III was ineffective in increasing O₂ consumption by rat liver cytosolic fraction and gave a much weaker ESR signal of an azo anion radical with both the liver cytosolic fraction, in the presence of NADH, and the hypoxanthine-xanthine oxidase system.     

ADP and ATP transport in mitochondria evidence for a metal-ion involved in transport catalysis by use of metallochromic indicators

This study introduces a new class of active-site directed probes with respect to ADP and ATP transport catalysis in rat liver mitochondria. The anionic monoazo dyes, e.g., $\text{p-(2-}\text{hydroxy}\text{-1-}\text{naphthylazo}\text{)}\text{naphtholsulfonic acid}$, are competitive inhibitors of carrier-mediated ADP uptake ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ 20–30 μM). The azo dyes also can displace the same amount of carrier-specific bound ADP as does carboxyatractyloside. Two essential substructures could be derived from a structure-activity study. Firstly, a sulfonic acid group in the para position relative to the azo bridge which becomes neutralized upon binding by a specifically located positive charge of the carrier protein. This electrostatic binding component, which presumably is represented by a strategic arginyl residue, seems to be essential for substrate binding as well as inhibitor binding. The second structural requirement for effective inhibition was found to be the $\text{o-}\text{hydroxy}$ or $\text{o,o′-}\text{dihydroxyazo}$ system, which is known to form stable complexes with metal ions by chelation. Experiments on prevention and reversal of dye-mediated inhibition revealed that the metal-chelating properties are responsible for the effects observed. In addition, using bovine serum albumin or the synthetic polymer Kollidone, inhibition could be prevented as well as abolished. It is postulated that a metal ion, possibly $\text{Mg}{}^{\mathrm{2+}}$, which is bound to the carrier protein plays an essential role for transport catalysis. The metal ion is assumed to form a functional ternary complex, i.e., a metal bridge complex between the carrier protein and its substrate.     

The metallochromic indicator dye Arsenazo III forms 1: 1 complexes with caffeine

The metallochromic indicator dye, Arsenazo III, forms a 1:1 complex with caffeine, a methylxanthine. Binding is accompanied by a wavelength-dependent shift in the absorption spectrum of the dye. The magnitude of the absorption change is significant at wavelengths typically used to monitor intracellular calcium ion. The equilibrium constant for the caffeine-dye reaction is approx. 20 mM. The complex has a differential molar extinction coefficient of ?5.05 · 10³ M^?1 · cm^?1 at 630 nm.     

A comparison of measurements of intracellular Ca by Ca electrode and optical indicators

Squid giant axons were injected with aequorin or arsenazo III and impaled with a Ca-sensing electrode. The light output of aequorin or the spectrophotometer output when measuring arsenazo was compared with the voltage output of the electrode when the squid axon was depolarized with high-K solutions, when the seawater was made Na-free, or when the axon was tetanized for several minutes. The results from these treatments were that the optical response rose (as much as 50-fold) with all treatments known to increase Ca entry, while the electrode remained unaffected by these treatments. If axons previously subjected to Ca load are treated with electron-transport poisons such as CN, it is known that [Ca]_i rises after a time necessary to deplete ATP stores. In such axons one expects a rise of [Ca]_i in axoplasm which does not necessarily have to be uniform although the source of such Ca is the mitochondria and these are uniformly distributed in axoplasm. Under conditions of CN application, the optical signals from aequorin or arsenazo and Ca electrode output do rise together when [Ca]_i is high, but there is a region of [Ca]_i concentration where aequorin light output or arsenazo absorbance rises while electrode output does not. Axons not loaded with Ca but injected with apyrase and vanadate have mitochondria that still retain some Ca and this can be released by CN in a truly uniform manner. The results show that such a release (which is small) can be readily measured with aequorin, but again the Ca electrode is insensitive to such [Ca]_i change.     

Calcium buffering in presynaptic nerve terminals. Free calcium levels measured with arsenazo III

The particulate fraction from osmotically shocked synaptosomes (‘synaptosomal membranes’) sequesters Ca when incubated with ATP-containing solutions. This net accumulation of Ca can reduce the free [Ca²⁺] of the bathing medium to sub-micromolar levels (measured with arsenazo III). Two distinct types of Ca sequestration site are responsible for the Ca²⁺ buffering. One site, presumed to be smooth endoplasmic reticulum, operates at low [Ca²⁺] (less than 1 μM), and has a relatively small capacity. Ca sequestration at this site is prevented by the Ca²⁺ ionophore, A-23187, but not by mitochondrial poisons. The second (mitochondrial) site, in contrast, is blocked by the mitochondrial uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone, and oligomycin. Since the intraterminal organelles can buffer [Ca²⁺] to about 0.3–0.5 μM, this may be an upper limit to the normal resting level of [Ca²⁺]_i in nerve terminals. In the steady state, total cell Ca and [Ca²⁺]_i will be governed principally by Ca transport mechanisms in the plasmalemma; the intracellular organelle transport systems then operate in equilibrium with this [Ca²⁺]. During activity, however, Ca rapidly enters the terminals and [Ca²⁺]_i rises. The intracellular buffering mechanisms then come into play and help to return [Ca²⁺]_i toward the resting level; the non-mitochondrial Ca sequestration mechanism probably plays the major role in this Ca buffering.     

Genetically encoded calcium indicators for studying long-term calcium dynamics during apoptosis

Intracellular calcium release is essential for regulating almost all cellular functions. Specific spatio-temporal patterns of cytosolic calcium elevations are critical determinants of cell fate in response to pro-apoptotic cellular stressors. As the apoptotic program can take hours or days, measurement of long-term calcium dynamics are essential for understanding the mechanistic role of calcium in apoptotic cell death. Due to the technical limitations of using calcium-sensitive dyes to measure cytosolic calcium little is known about long-term calcium dynamics in living cells after treatment with apoptosis-inducing drugs. Genetically encoded calcium indicators could potentially overcome some of the limitations of calcium-sensitive dyes. Here, we compared the performance of the genetically encoded calcium indicators GCaMP6s and GCaMP6f with the ratiometric dye Fura-2. GCaMP6s performed as well or better than Fura-2 in detecting agonist-induced calcium transients. We then examined the utility of GCaMP6s for continuously measuring apoptotic calcium release over the course of ten hours after treatment with staurosporine. We found that GCaMP6s was suitable for measuring apoptotic calcium release over long time courses and revealed significant heterogeneity in calcium release dynamics in individual cells challenged with staurosporine. Our results suggest GCaMP6s is an excellent indicator for monitoring long-term changes cytosolic calcium during apoptosis.     

New red-fluorescent calcium indicators for optogenetics,photoactivation and multi-color imaging

Most chemical and, with only a few exceptions, all genetically encoded fluorimetric calcium (Ca²⁺) indicators (GECIs) emit green fluorescence. Many of these probes are compatible with red-emitting cell- or organelle markers. But the bulk of available fluorescent-protein constructs and transgenic animals incorporate green or yellow fluorescent protein (GFP and YFP respectively). This is, in part, not only heritage from the tendency to aggregate of early-generation red-emitting FPs, and due to their complicated photochemistry, but also resulting from the compatibility of green-fluorescent probes with standard instrumentation readily available in most laboratories and core imaging facilities. Photochemical constraints like limited water solubility and low quantum yield have contributed to the relative paucity of red-emitting Ca²⁺ probes compared to their green counterparts, too. The increasing use of GFP and GFP-based functional reporters, together with recent developments in optogenetics, photostimulation and super-resolution microscopies, has intensified the quest for red-emitting Ca²⁺ probes. In response to this demand more red-emitting chemical and FP-based Ca²⁺-sensitive indicators have been developed since 2009 than in the thirty years before.     

Fluorescent indicators for imaging membrane potential of organelles

Plasma membrane potential is a key driver of the physiology of excitable cells like neurons and cardiomyocytes. Voltage-sensitive fluorescent indicators offer a powerful complement to traditional electrode-based approaches to measuring and monitoring membrane potential. Intracellular organelles can also generate membrane potential, yet the electrode- and fluorescent indicator-based approaches used for plasma membrane potential imaging are difficult to implement on intact organelles in their native environment. Here, we survey recent advances in developing and deploying voltage-sensitive fluorescent indicators to interrogate organelle membrane potential in intact cells.     

Determination of Mn(II) and Co(II) with Arsenazo III

Complex formation between Arsenazo III and Mn²⁺ and Co²⁺ at equilibrium has been investigated at pH 7.2, and the stoichiometry and stability of the complexes have been determined. The data indicate that Arsenazo III is suitable for determination of Mn²⁺ and Co²⁺ on the micromolar scale. The dissociation constants of the phosphate complexes of Mn²⁺ and Co²⁺ at pH 7.2 were estimated with Arsenazo III as 3.6 and 10 mM, respectively.     

Characterization of calcium liberation from a human platelet membrane fraction

Calcium efflux and EGTA-induced calcium release from an internal platelet membrane fraction have been studied after the oxalate-supported calcium uptake had reached steady state. Increasing external calcium concentrations stimulate the calcium efflux velocity, with an apparent half-maximal stimulation at about 5 μM outside calcium concentration and a maximal velocity of calcium efflux of $\text{4.66 ± 2.32}\text{nmol}\text{·}\text{min}{}^{\mathrm{?1}}\text{·}\text{mg}{}^{\mathrm{?1}}$. Moreover, the ratio of the liberated calcium on the loaded calcium seems to be independent of the increasing external calcium concentration. Increasing the calculated internal calcium concentration by varying the oxalate potassium concentration from 10 mM to 1 mM results in an increase of the liberated calcium from the membrane vesicles from 7.4% to 63%, respectively, without changing the calcium efflux velocity. Similar conclusions can be drawn from the observation of results from the calcium efflux and EGTA-induced calcium release methods. Moreover, calcium pump reversal does not seem to be responsible for the calcium efflux or calcium release. All these different points added to the previously described regulation of calcium efflux by the catalytic subunit of cAMP protein kinase suggest us that the mechanism of calcium liberation by the platelet membranes is different from the calcium uptake.     

A proposed framework for developing indicators of ecosystem health

Considerations involved in developing a suite of indicators to monitor regional environmental health, similar in conception to management use of leading economic indicators, are described. Linkages between human activities and well being and the state of the environment are considered essential to the evaluation of general environmental health. Biogeochemical and socioeconomic indicators are mutually affected by environmental degradation and examples of both categories of indicators are described. Desirable properties in indicators of environmental health vary with their specific management use. Different indicators are called for when collecting data to assess the adequacy of the environment, monitor trends over time, provide early warning of environmental degradation, or diagnose the cause of an existing problem. Tradeoffs between desirable characteristics, costs, and quality of information are inevitable when choosing indicators for management use. Decisions about what information to collect for which purpose can be made more rationally when available indicators are characterized and matched to management goals.     

The binding of arsenazo III to cell components

The Ca²⁺ indicator, arsenazo III, binds to subcellular fractions of rabbit skeletal muscle with sufficient affinity that in living muscle containing 1–2 mM arsenazo III, the estimated free arsenazo III concentration is only 50–200 μM; 80–90% of the bound arsenazo III is associated with soluble proteins.The binding of arsenazo III to soluble proteins decreases the optical response of the dye to Ca²⁺; this is due to a decrease in the affinity of the protein-bound dye for Ca²⁺. Approximately half of the bound arsenazo III is released from the particulate fraction and soluble proteins upon addition of 5 mM Ca²⁺, suggesting that the Ca-arsenazo complex has lower affinity for the protein binding sites than the free dye.The Ca²⁺ binding to the soluble protein fraction of rabbit skeletal muscle is attributable largely to its parvalbumin content.     

In vitro calibration of the equilibrium reactions of the metallochromic indicator dye antipyrylazo III with calcium.

The equilibrium reactions of the metallochromic indicator dye Antipyrylazo III with calcium at physiological ionic strength have been investigated spectrophotometrically. Dye absorbance as a function of wavelength was measured at various total dye and calcium concentrations. Analysis of the absorbance spectra indicated that at pH 6.9 at least three calcium:dye complexes form, with 1:1, 1:2, and possibly 2:2 stoichiometries. The dissociation constant and the changes in dye extinction coefficients on formation of the 1:2 complex, the main complex which forms when Antipyrylazo III is used to study cytoplasmic calcium transients, have been characterized.     

Interaction of the innate immune system with positive-strand RNA virus replication organelles

The potential health risks associated with (re-)emerging positive-strand RNA (+RNA) viruses emphasizes the need for understanding host-pathogen interactions for these viruses. The innate immune system forms the first line of defense against pathogenic organisms like these and is responsible for detecting pathogen-associated molecular patterns (PAMPs). Viral RNA is a potent inducer of antiviral innate immune signaling, provoking an antiviral state by directing expression of interferons (IFNs) and pro-inflammatory cytokines. However, +RNA viruses developed various methods to avoid detection and downstream signaling, including isolation of viral RNA replication in membranous viral replication organelles (ROs). These structures therefore play a central role in infection, and consequently, loss of RO integrity might simultaneously result in impaired viral replication and enhanced antiviral signaling. This review summarizes the first indications that the innate immune system indeed has tools to disrupt viral ROs and other non- or aberrant-self membrane structures, and may do this by marking these membranes with proteins such as microtubule-associated protein 1A/1B-light chain 3 (LC3) and ubiquitin, resulting in the recruitment of IFN-inducible GTPases. Further studies should evaluate whether this process forms a general effector mechanism in +RNA virus infection, thereby creating the opportunity for development of novel antiviral therapies.     

Stoichiometry of the reactions of calcium with the metallochromic indicator dyes antipyrylazo III and arsenazo III.

A method for determining the stoichiometry of one-product reactions involving a metal ion and an organic ligand is presented and applied to the reactions of calcium and magnesium with the metallochromic dyes Antipyrylazo III and Arsenazo III. The method consists of fitting titration data, obtained in solutions buffered for the metal, with theoretical functions that include: (a) the dependence of product concentration on the concentration of both reactants, (b) the relationship between metal ion concentration and total amount added in the presence of the buffer, and (c) a correction for the amount of metal ion that binds to the organic ligand. It is shown that the products of the reactions of Antipyrylazo III with calcium and magnesium are CaD2 and MgD, respectively. The product formed between calcium and Arsenazo III at [Ca2+] over 20 microM is CaD2, other products accumulating at lower [Ca2+]. The kinetics of the Antipyrylazo III:Ca reaction are rapid under conditions in which this dye has been applied to measure calcium transients in skeletal muscle fibers. The present results provide a calibration for previous studies with Antipyrylazo III in muscle fibers.     

Calcium binding to metallochromic dyes and calmodulin in the presence of combined, AC-DC magnetic fields.

The possibility that weak, ac and dc magnetic fields in combination may affect binding equilibria of calcium-ions (Ca2+) was investigated with two metallochromic dyes as calcium-binding molecules: murexide and arsenazo III. Calcium-dye equilibria were followed by measuring solution absorbances with a fiber-optic spectrophotometer. A Ca(2+)-arsenazo solution was also used indirectly to monitor the binding of Ca2+ to calmodulin. Parallel, ac and dc magnetic fields were applied to each preparation. The ac magnetic field was held constant during each of a series of experiments at a frequency in the range between 50 and 120 Hz (sine wave) or at 50 pps (square wave) and at an rms flux density in the range between 65 and 156 microT. The dc magnetic field was then varied from 0 to 299 microT at 1.3 microT increments. The magnetic fields did not measurably affect equilibria in the binding of metallochromic dyes or calmodulin to Ca2+.